JPH058024A - Molten metal holding furnace - Google Patents

Abstract

PURPOSE:To eliminate interruption of dip-out work of molten steel and to make sure of degassing in the dip-out side by arranging gas injecting means at furnace bottom in lower side of a filter for filtering the molten metal and arranging a piping for supplying gas so as to face a pouring hole to the gas injecting means. CONSTITUTION:In a molten metal holding furnace arranged so as to partition an inner space in the furnace 10 with a parting wall 15 and the filter for filtering the molten metal 22 and arrange horizontal type submerged tubes 20 incorporating exothermic body 19 to horizontal direction, the piping for gas supplying pipe 24 is arranged so as to execute degassing from lower side of the filter 22 for filtering the molten metal. Gas for supplying from the piping 24 is made to fine bubbles with the filter 25 for injecting gas and discharged in the molten metal, and this gas is passed through the filtering the molten metal and discharged in the air. The gas is made so as not to flow to the dip-out side 32 with an extending part 27 extended to lower end part of the parting wall 15.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a melting and holding furnace, and more particularly to a melting and holding furnace provided with a heating element for holding molten metal in a molten state.

[0002]

2. Description of the Related Art Various metals are melted and poured into a mold,
When casting machine parts and the like by this, generally, without melting molten metal taken out of the melting furnace and directly injected into the mold, the molten metal is once transferred from the melting furnace to the melting holding furnace,
In this melting and holding furnace, the molten metal is held in a molten state, and the molten metal is taken out by a predetermined amount for casting.

A conventional melting and holding furnace is, for example, Japanese Patent Publication No. 63-
No. 7318 is disclosed. In this melting and holding furnace, for example, as shown in FIG. 3, a ceramic filter 2 is vertically disposed so as to divide the inside of the furnace 1 into two parts, and a dipping tube 3 containing a heating element is provided on both sides of the ceramic filter 2. I am trying to distribute. The heating element in the dip tube 3 maintains the molten state of the molten metal.

[0004]

In such a melting and holding furnace, when the molten metal is in contact with water in the air when it is used under high temperature and high humidity, especially in summer weather conditions, hydrogen gas is generated in the molten metal. Increasing gradually, product defects due to gas increase. For this reason, it is necessary to remove the gas from the molten metal in advance and inject it into the mold. Therefore, conventionally, for example, the gas injection pipe 4 is inserted on the injection side, and nitrogen gas is injected from the gas injection pipe 4 to perform degassing and slag removal.

When the amount of gas in the melting and holding furnace increases in this way, the gas is ejected from the gas injection pipe 4 for degassing. Since the injection pipe 4 is not inserted on the pumping side, the pumping operation of the molten metal is not interrupted, but the presence of the filter 2 in the middle prevents the degassing of the molten metal on the core pumping side. There is.

FIG. 4 shows another conventional melting and holding furnace. In this melting and holding furnace, the ceramic filter 2 is arranged horizontally between the lower end side of the intermediate partition wall 5 and the furnace wall. In this case also, the gas injection pipe 4 is inserted on the injection side to perform degassing. Therefore, such a melting and holding furnace also has the same problems as described above.

The present invention has been made in view of the above problems, and it is possible to reliably perform degassing on the pumping side without interrupting the molten metal pumping operation. It is intended to provide a melting and holding furnace.

[0008]

According to a first aspect of the present invention, there is provided a melting and holding furnace including a heating element for holding a molten metal in a molten state, wherein a partition wall having a gap between a lower end and a furnace bottom is provided. A filter for arranging the melt in the furnace and dividing the interior by the partition wall into two is provided between the partition wall and the furnace wall on the molten metal injection side. A gas ejection means for degassing the molten metal is provided on the lower side.

In a second aspect based on the first aspect, the lower end side of the partition wall has an extension portion extending below the melt filtration filter, and the extension portion extends the gas. The gas supplied from the jetting means is prevented from flowing to the pumping side opposite to the partition wall where the molten metal filtering filter is provided.

[0010]

According to the first aspect of the invention, the gas is supplied through the gas injection means and is injected into the molten metal in the furnace through the gas filter. In addition, this gas comes out into the atmosphere through the molten metal filtering filter disposed on the gas.

According to the second aspect of the invention, the gas ejected through the gas ejecting means is prevented from flowing to the pumping side on the opposite side by the extending portion on the lower end side of the partition wall.
The gas will surely pass through the filter for filtration and escape into the atmosphere through the injection side.

[0012]

1 and 2 show a melting and holding furnace according to an embodiment of the present invention. The melting and holding furnace has a rectangular parallelepiped shape, and has a brick furnace wall 11 on the inside and an outside thereof. An outer plate 1 made of an iron plate joined to a brick 11 so as to cover the
2 and. The furnace 10 has an opening 13 at the upper portion thereof, and a heat shield cover 14 is attached to the upper portion of the furnace 10 so as to cover a substantially middle portion of the opening 13. A partition wall 15 is provided below the heat shield cover 14 between furnace walls facing each other. Partition wall 1
The lower end side of 5 has a gap between it and the furnace bottom, and constitutes a molten metal passage 16.

Immersion pipes 20 accommodating heating elements 19 are arranged on both sides of the partition wall 15 of the furnace 10. The dip pipe 20 is horizontally arranged in the furnace at a predetermined distance from the furnace bottom, and both ends thereof are supported by mutually facing furnace walls, as shown in FIG. Then, the terminal 21 of the heating element 19 is inserted so as to penetrate the one furnace wall 11.
Is drawn out, and an electric current is passed through this terminal 21, so that the heating element 19 is caused to generate heat.

A molten metal filtering filter 22 is disposed between the partition wall 15 and the furnace wall 11 on the right side in FIGS. 1 and 2. The filter 22 for filtration is for filtering the molten metal injected from above. A gas jetting filter 23 is arranged below the molten metal filtering filter 22 and at the bottom of the furnace. Then, for example, three gas supply pipes 24 are provided so as to be connected to the gas jetting filter 23. The gas ejection filter 23
May be a thin pipe made of quartz or graphite, but a porous ceramic filter is preferred. When the gas in the molten metal passes through the filter 23 and is discharged into the molten metal, it becomes fine bubbles to enhance the degassing effect.

With the above-mentioned structure, the molten metal is injected into the injection side 31 on the right side of the partition wall 15 of the melting and holding furnace 10 from above as shown by the arrow in FIG. This molten metal is heated by the heat of the heating element 19 in the dip tube 20
Holds the melted state within 0. Then, since the molten metal is gradually pumped out from the pumping side 32 on the opposite side, the molten metal injected into the pouring side 31 passes through the molten metal filtering filter 22 and passes through the molten metal passage 16 below the partition wall 15. It flows through to the pumping side 32. In this way, the molten metal is gradually pumped out of the furnace 10 and poured into the mold to manufacture mechanical parts.

Further, in this melting and holding furnace, a gas injection filter 23 is arranged below the molten metal filtration filter 22 on the injection side 31, and a gas supply pipe 24 is provided below the gas injection filter 23. The outlet is open. Therefore, the gas supplied through the supply pipe 24 is
It is dispersed in the molten metal through the porous gas injection filter 23.

Moreover, the dispersed gas comes out into the atmosphere on the injection side 31 through the melt filter 22 for filtering the oxide film in the melt. Moreover, the lower end side of the partition wall 15 extends below the molten metal filtering filter 22, and the tip end portion forms the extending portion 27. The gas ejected into the molten metal through the gas filter 23 by the extending portion 27 cannot escape to the pumping side 32.

Moreover, since the space where the gas jetting filter 23 is provided is communicated with the pumping side 32 through the molten metal passage 16 below the partition wall 15, the molten metal on the pumping side 32 is degassed. Will be done easily. Further, since the gas ejected through the gas ejecting filter 23 is further floated through the molten metal filtering filter 22, the oxide film filtered by the molten metal filtering filter 22 is injected on the injection side 31.
It becomes easier to float up and the filter effect is maintained. Further, since the oxide film itself is reduced, the degassing effect is increased.

As described above, the melting and holding furnace according to this embodiment is
The furnace 10 is formed by the partition wall 15 and the molten metal filtration filter 22.
In the melting and holding furnace, which divides the internal space of the molten metal, and horizontally arranges the horizontal dip pipe 20 accommodating the heating element 19, a gas supply pipe capable of degassing from the lower side of the molten metal filter 22. Twenty-four pipes are arranged. Moreover, the gas supplied from the pipe 24 becomes fine bubbles by the gas injection filter 23 and is discharged into the molten metal.
The structure is such that this gas is discharged into the atmosphere through the melt filtration filter 22, and the gas is prevented from flowing to the pumping side 32 by the extending portion 27 extending to the lower end of the partition wall 15. There is.

Therefore, according to such a configuration, the injection side 3
Since it is not necessary to insert the gas injection pipes from above into both the 1 and the pumping side 32, there is no need to interrupt the pumping or pouring operation of the molten metal to perform degassing. Further, since the gas for degassing is jetted out below the molten metal filtering filter 22 which communicates with the pumping side 32 by the molten metal passage 16 below the extending portion 27 of the partition wall 15, It is also possible to easily degas the side 32.

[0021]

According to the first aspect of the present invention, a partition wall having a gap between the lower end side and the furnace wall is arranged in the furnace, and the partition wall divides the interior into two parts. A filter for filtering the molten metal should be placed between the furnace wall and the furnace, and a gas injection means should be provided on the bottom of the furnace below the molten metal filtration filter, and a gas supply pipe should be provided so that the spout faces the gas injection means. It is the one.

Therefore, the gas injected from the gas supply pipe is injected into the molten metal in the lower portion of the molten metal filtering filter through the gas ejection means. Then, this gas passes through the melt filtration filter and escapes to the atmosphere side. Further, since the gas injection is communicated with the pumping side by the gap on the lower end side of the partition wall, the molten metal on the pumping side can be easily degassed. Moreover, since the gas is injected from the bottom of the furnace,
There is no need to interrupt the injection of molten metal or the pumping of molten metal when degassing.

A second aspect of the invention is that the partition wall has an extension portion at the lower end side which extends below the melt filtration filter.
The extension portion prevents the gas supplied through the pipe from flowing to the pumping side opposite to the partition wall where the molten metal filtering filter is provided. Therefore, according to such a structure, particularly, the gas injected through the gas injection means does not flow to the pumping side by the extending portion, and is surely discharged to the atmosphere on the injection side.

[Brief description of drawings]

FIG. 1 is a plan view of a melting and holding furnace of an example.

FIG. 2 is a vertical sectional view of the melting and holding furnace.

FIG. 3 is a vertical sectional view of a conventional melting and holding furnace.

FIG. 4 is a vertical sectional view of a conventional melting and holding furnace.

[Explanation of symbols]

10 furnaces 11 Furnace wall (brick) 12 Iron plate (outer plate) 13 openings 14 heat shield cover 15 partition walls 16 molten metal passage 19 heating element 20 Immersion tube 21 terminals 22 Filter for molten metal filtration 23 Gas ejection filter 24 gas supply pipe 27 Extension 31 Injection side 32 Pumping side

Claims (2)

[Claims] 1. A melting and holding furnace including a heating element for holding a molten metal in a molten state, wherein a partition wall having a gap between a lower end and a furnace bottom is arranged in the furnace, and the partition wall. The inside of the molten metal is divided into two parts, and a filter for filtering the molten metal is arranged between the partition wall and the furnace wall on the molten metal injection side. Further, a gas jet for degassing the molten metal is provided below the molten metal filtering filter. A melting and holding furnace characterized in that means is provided. 2. The partition wall has a lower end side that has an extending portion that extends below the molten metal filtering filter, and the gas supplied from the gas ejecting means to the dividing wall by the extending portion. On the other hand, the melting and holding furnace according to claim 1, wherein the melt holding furnace is configured so as not to flow to a pumping side opposite to a section where the molten metal filtering filter is provided.